Immune complex binding to erythrocyte-CR1 (CD 35), CR1 expression and levels of erythrocyte-fixed C3 fragments in SLE outpatients

Erythrocytes (E) from a cross-sectional group of 22 outpatients with systemic lupus erythematosus (SLE) and/or mixed connective tissue disease (MCTD), the majority without active disease (n = 14), were analyzed for CR1 antigen expression and capacity to bind complement opsonized, radiolabelled immune complexes (IC). Furthermore, E-bound C3 fragments and the plasma C3d concentration were determined. E-bound C3b/iC3b fragments were not elevated in patients with SLE, whereas E from 11 out of 22 SLE patients had increased C3d levels which correlated with the plasma C3d concentration (Rs 0.73, p less than 0.001). E-fixed C3d fragments did not affect the binding of Mab or preopsonized IC to E-CR1 and were not correlated with disease activity or medical treatment. Antigen expression of E-CR1 measured by ELISA or agglutination showed positive correlation with the IC binding capacity of E-CR1 (Rs 0.92 and 0.72 respectively, p less than 001). The IC binding capacity of E-CR1 from SLE patients was significantly reduced (p less than 0.005), whereas the antigen expression of CR1 (ELISA) on E from the patients did not differ from that of E from healthy donors (p greater than 0.1). E-CR1 antigen was measured by Mab reacting with an epitope outside the IC-binding site of E-CR1. E-CR1 antigen expression or IC binding showed no correlation either with disease activity or prednisolone treatment. However, 4 og 5 patients with MCTD and 4 of 5 patients receiving Imurel were found to have low E-CR1 expression and capacity to bind IC. Thus, measurement of antigenic E-CR1 in a cross-sectional group of SLE outpatients by use of Mab reacting with an epitope outside the ligand-binding region of CR1 did not reveal a significantly reduced CR1 expression. However, an assay for CR1-mediated IC binding showed a clearly reduced E-CR1 function.     

Reduced Erythrocyte CR1 (CD 35) Receptor Function and Complement Opsonization in Factor I-Deficient Patients is Restored by Plasma Infusion

Erythrocytes (E) from three factor I-deficient patients were investigated for surface-bound complement factors and CR1 (CD 35) expression and function. The E were coated with C4b, C3b, and factor H. Following plasma infusion or in vitro incubation of the patients' E with normal human serum (NHS) or purified factor I, cell-bound C4b and C3b could no longer be detected. The E now expressed C3d, and factor H was unaffected, indicating that factor H was bound to the C3d part of the C3b molecules, providing the co-factor for effective cleavage of E-bound C3b when purified factor I was added. The binding of monoclonal anti-CR1 antibodies (M710) to the patients' E was markedly reduced compared with control E, and was not normalized by treatment with NHS, probably because covalently bound C3d/factor H interfered with the binding of M710. By contrast, the reduced ability of the patients' E-CR1 to bind complement-opsonized immune complexes (IC) was normalized after plasma infusion. This shows that the impaired CR1 function was acquired and emphasizes the importance of performing functional CR1 assays. Complement opsonization of IC for binding to normal E was severely compromised in the patients' sera due to consumption of factor B and C3. After plasma infusion the opsonization capacity of the patients' sera was restored. Thus, two mechanisms of importance for normal clearance of IC were compromised in factor I-deficient patients: (1) the opsonization of IC for binding to E-CR1, and (2) the capacity of E-CR1 to bind opsonized complexes. Both dysfunctions were temporarily corrected by plasma infusion.     

Release of Immune Complexes bound to Erythrocyte Complement Receptor (CR1), with Particular Reference to the Role of Factor I

The release of 125I-bovine serum albumin (BSA)-anti-BSA immune complexes (IC) bound to human erythrocyte complement receptors (E-CR1) was studied. IC were complement-solubilized in normal human serum (NHS), and reacted with human erythrocytes at conditions optimal for binding of the IC to E-CR1. E-CR1-bound IC could be released by the addition of NHS or purified factor I. Factor I-deficient or I-depleted serum mediated no release, and addition of purified factor I restored the release. Factor H was not required for the release of IC. The kinetics of IC release was influenced by the NHS concentration, the presence of EDTA, and the time of prior storage of the erythrocytes at 4 degrees C. NHS (1:5 to 1:10) in the presence of EDTA caused nearly maximal release within 10-20 min at 37 degrees C. In the absence of EDTA the NHS-induced IC release was markedly slower. IC released within the first 30 min showed significant rebinding to new E. The release of IC was not associated with loss of the IC binding activity of E-CR1. The NHS-mediated release of IC could be inhibited by rabbit anti-CR1 and by a mixture of protease inhibitors. Release induced by purified factor I was also inhibited by protease inhibitors. The affinity of IC binding to E-CR1 was reduced after cleavage of CR1-bound C3b-IC to iC3b-IC by factor I.     

Interaction of complement-solubilized immune complexes (IC) with CR1 receptors on human erythrocytes. Polysulfated compounds inhibit IC binding and induce IC-release from CR1

The effect of the polysulfated compounds heparin, dextran sulfate, chondroitin sulfate and suramin, and non-sulfated poly-, oligo-, and monosaccharides on binding and release of complement-solubilized 125I BSA-anti BSA immune complexes (IC) reacting with complement C3b receptors (CR1) on human erythrocytes (E) was investigated. Following presolubilization of IC in normal autologous human serum (NHS) a clear dose-dependent inhibition of IC-binding to E-CR1 was obtained by addition of polysulfated compounds. The inhibitory effect was dependent on the sulfate content of the reagents used but independent of their anticoagulant activity as heparin preparations with high and low affinity for antithrombin III inhibited IC binding to E-CR1 to approximately the same extent. Dextran sulfate caused a stronger inhibition than heparin while chondroitin sulfate was inhibitory only at high concentrations. The inhibitory effect was exerted at the IC-C3b level as normal IC-binding occurred following preincubation of E with the polysulfated compounds. Non-sulfated saccharides showed no inhibition of IC binding to E-CR1. All polysulfated compounds, apart from chondroitin sulfate, induced a dose-dependent release of E-CR1 bound IC in the absence of NHS. No release was obtained by use of non-sulfated saccharides. Heparin induced IC-release was rapid (40-45% after 3 min) and incubation beyond 30 min caused only an insignificant further release of IC from E-CR1. Following release of IC the E-CR1 retained full binding capacity for freshly added IC-C3b.     

The roles of complement receptors type 1 (CR1, CD35) and type 3 (CR3, CD11b/CD18) in the regulation of the immune complex-elicited respiratory burst of polymorphonuclear leukocytes in whole blood

The binding of immune complexes (1C) to polymorphonuclear leukocytes (PMN) and the consequent respiratory burst (RB) were investigated in whole blood cell preparations suspended in 75% human serum, using flow cytometry. Blockade of the complement receptor (CR)1 receptor sites for C3b on whole blood cells using the monoclonal antibody (mAb) 3D9 resulted in a 1.9-fold increase in the IC-elicited PMN RB after 5 min of incubation, rising to 3.1-fold after 40 min. This enhancement was not due to increased IC deposition on PMN. Blockade of CR3 abrogated the mAb 3D9-induced rise in RB activity and inhibited the IC binding to PMN in a whole blood cell preparation, with or without mAb 3D9, by approximately 40% from 15–40 min while reducing their RB over 40 min to approximately one third. Blockade of CR1 on either erythrocytes (E) or leukocytes, before mixing the populations, revealed that the potentiation of the RB by mAb 3D9 was associated with abrogation of E-CR1 function, whereas blockade of leukocyte-CR1 had a diminishing effect. Exposure to IC at high concentrations induced release of both specific and azurophilic granule contents from PMN. The latter was CR3 dependent in that blockade of the receptor inhibited the lactoferrin release by one third during 40 min of incubation. In conclusion, CR3 plays a significant role in the IC-mediated generation of an RB and release of specific granules by PMN, while CR1 on whole blood cells, primarily E CR1, restricts the IC-elicited RB in PMN. We propose that CR1 in whole blood promotes the degradation of IC-bound iC3b to C3dg, thereby rendering the IC inaccessible for binding to CR3.     

Co-operation between human CR1 (CD35) and CR2 (CD21) in internalization of their C3b and iC3b ligands by murine-transfected fibroblasts

CR1 and CR2 are expressed as associated proteins on the B-lymphocyte surface. To investigate their respective contributions to the internalization of C3 fragments, transfected murine fibroblasts expressing human CR1, CR2, or both CR1 and CR2 were produced. CR1- and CR1-CR2-expressing cells bound C3b and C3b-dimer whereas CR2- and CR1-CR2-expressing cells bound iC3b and C3de. In all cases, maximum binding was achieved at low ionic strength. CR1-CR2-positive cells internalized two- to threefold more C3b and 1.5-fold more iC3b than CR1- and CR2-single-positive cells, respectively. Internalization of the anti-CR1 antibody J3D3, or C3de was at the same level, in both double-transfected and single-transfected cells. Furthermore, the internalization of C3b dimer by CR1-CR2 cells was impaired in the presence of OKB7, an anti-CR2-blocking antibody, but it was not altered in CR1 cells. Taken together, these findings suggest that CR1 and CR2 collaborate to internalize C3b and iC3b proteins. We suggest that the induction of conformational changes of the ligands enhances their binding to both receptors.     

Modulation of neutrophil expression of C3b receptors (CR1) by soluble monomeric human C3b

Upon incubation at 37 degrees C with purified human C3b (500 micrograms/ml), polymorphonuclear neutrophils (PMN) were found to express up to 50% more C3b receptors (CR1) than PMN incubated with buffer alone. This up-regulation of CR1, assessed by the binding of radiolabeled CR1-specific monoclonal antibody, was dependent on the dose of C3b, occurred within 10-20 min and was stable for at least 90 min. PMN incubated with C3b also demonstrated enhanced CR1-dependent binding functions, such as EC3b rosette formation and phagocytosis of EIgGC3b particles. C3b at a concentration of 500 micrograms/ml induced up to 90% increase in the attachment or the phagocytic index. However, CR1 remained unable to promote phagocytosis of EC3b intermediates. Fc receptor-mediated functions were unaffected by the treatment with C3b. The active factor was characterized as monomeric C3b and, in particular, shown to be distinct from C5a. C3b purified by anion-exchange fast protein liquid chromatography on a Mono Q column or eluted from a monoclonal anti-C3b-Sepharose retained its modulating activity, while native C3 or C3 fragments such as iC3b, C3c or C3d,g were ineffective.     

Influence of Processing by Erythrocyte C3b/C4b Receptors (CR1) on Binding of Immune Complexes to Raji Cells and Polymorphonuclear Granulocytes

The binding of 125I-labelled bovine serum albumin (BSA)-anti-BSA immune complexes (IC) to Raji cells and polymorphonuclear (PMN) cells in vitro was studied. The IC were reacted for 1 h at 37 degrees C with normal human serum (NHS) diluted 1:2 in the presence or absence of human erythrocytes (E) before presentation for Raji cells or PMN cells. The IC showed a two to three fold increased binding to C3d, g receptors (CR2) on Raji cells, when E-CR1 had been present during the reaction with NHS, compared to IC similarly reacted with NHS only. Blocking of the E-CR1 by a polyclonal anti-CR1 antibody reduced the subsequent binding of IC to Raji cells to the same level as that obtained with IC reacted with serum only. Binding to PMN granulocytes of IC reacted with NHS in the presence of E-CR1 showed a 60% reduction compared to the binding of IC reacted with NHS only. It is concluded that interaction of complement-reacted IC with CR1 on erythrocytes leads to a more efficient generation of CR2-binding C3d, g-containing IC with reduced reactivity to PMN cells.     

Contribution of CR3, CD11b/CD 18 to cytolysis by human NK cells

The complement receptor CR3 molecule functions in direct intercellular contacts mediated by its beta chain, CD18. Similarly to the Fc receptor (CD16), CR3 is a marker of human natural killer cells. We have shown that opsonization of NK targets with iC3b leads to their increased lytic sensitivity. Opsonization could be achieved by incubating certain B and T cell lines in human serum. The expression of CR2 was a prerequisite for C3 fragment fixation. The CR2 negative cell line, P3HR1 could be opsonized by incubation in human serum when induced to express the EBV envelope glycoprotein gp350. C3b or iC3b could also be deposited artificially on cell surfaces by chemical coupling to surface reactive antibodies. Similarly to the function of macrophages and monocytes, contact with opsonized targets exclusively through the iC3b binding site of CR3 did not seem to trigger NK function. We attempted to clarify the functional role of other CR3 ligands. The beta chain of the molecule, CD18, was essential to the NK effect. The NK targets did not seem to interact with the beta-glucan binding epitope on the alpha chain of CR3, CD11b. On the other hand, the cytolytic function could be enhanced through this epitope with the appropriate ligand.     

Inefficient Binding of IgM Immune Complexes to Erythrocyte C3b–C4b Receptors (CR1) and Weak Incorporation of C3b–iC3b into the Complexes

The binding of soluble complement-reacted IgM immune complexes (IC) to erythrocyte (E) C3b–C4b receptors (CRI) and the incorporation of C3b–iC3b into solid phase IgM-IC was investigated. The optimal binding of liquid phase IgM-IC to E-CRI was obtained with IC formed at moderate antibody excess, but the binding was low (2–3%) when compared to the binding of the corresponding IgG-IC (50–60%). Solid phase IC were prepared by coming microwells with heat-aggregated bovine serum albumin (BSA) followed by incubation with rabbit IgM anti-BSA antibody. The IC were reacted with human serum at 37°C. The binding of C3b–iC3b was determined by use of biotinylated F(ab')₂ antibodies to C3b-C3c and avidin-coupled alkaline phosphatase. The incorporation of C3b–iC3b into solid-phase IgM-IC increased when increasing amounts of IgM antibody were reacted with the antigen. The binding reaction was slow, reaching a maximum after about 2 h at 37°C. The binding of C3b–iC3b to the IgM-IC was remarkably inefficient when compared to the incorporation into IgG-IC reacted with the same amounts of BSA-precipitating antibody.     

Binding of Cryptococcus neoformans to heterologously expressed human complement receptors.

Previously, we demonstrated that monoclonal antibodies (MAb) directed against any of the three defined complement receptors (CR) for the third component of complement (CR1, CR3, and CR4) profoundly inhibited the binding of serum-opsonized Cryptococcus neoformans to monocyte-derived macrophages. These studies suggested either that a synergistic interaction between multiple CR was required for optimal binding of C. neoformans or that the MAb were exerting nonspecific effects (such as receptor coassociation). In the present studies, we took a novel approach to dissecting out the contributions of individual receptors to binding of a microbial pathogen. Chinese hamster ovary (CHO) cells stably transfected with human CR1, CR3, or CR4 were challenged with serum-opsonized C. neoformans. We found that CHO cells transfected with any of the three receptors bound C. neoformans, with the avidity of binding to CR3 being the greatest followed in decreasing order by CR1 and CR4. Following binding of C. neoformans to transfected CHO cells, most organisms remained surface attached only, although for each receptor a significant percentage (18.5 to 27.3%) of C. neoformans was internalized. Both C. neoformans and sheep erythrocytes that were selectively opsonized with the fragments of the third component of complement, C3b and iC3b, were bound preferentially by CHO cells transfected with CR1 and CR3, respectively. These data establish CR1, CR3, and CR4 as receptors independently capable of binding C. neoformans opsonized with fragments of C3. Moreover, our study demonstrates the usefulness of transfected cell lines as a powerful tool for identifying the contribution of individual receptors to the binding of a microbial pathogen.     

Ligand specificities of mouse complement receptor types 1 (CR1) and 2 (CR2) purified from spleen cells

Murine complement receptor type 2 (MCR2) is homologous to humanCR2, whereas murine CR1 (MCR1) is structurally and evolutionarydifferent from human CR1. Since ligand specificities of MCR1and MCR2 are not completely clarified, we analyzed their functionalcharacteristics to correlate them with structural informationobtained in molecular biological studies. MCR1 and MCR2 purifiedfrom spleen cells were incubated with thlol-Sepharose bearingmurine C3b, IC3b, or C3d in the presence or absence of variousanti-MCR1 or-MCR1/MCR2 mAbs. Bound and free MCR1 and MCR2 werequantitated by Western biotting or two-site immunoradiometricassay. MCR2 bound to C3d and IC3b similarly efficiently, and5-fold less efficiently to C3b. These bindings were completelyinhibited by MCR1/MCR2-crossreactive antibodies 7G6 and 4E3.MCR1 bound to C3b efficiently and this was partially inhibitedby MCR1-monospecific antibody 8C12, but not by 7G6 and 4E3.Combinations of 8C12 and 7G6 or 4E3 completely inhibited MCR1binding to C3b. Therefore, two binding sites, one unique toMCR1 and the other shared with MCR2, are involved in MCR1 bindingto C3b. MCR1 bound also to C3d and this was completely inhibitedby 7G6 and 4E3. The binding of this solubilized MCR1 to C3dwas as efficient as that of MCR2 to C3d. It seems, therefore,that the site shared by MCR1 and MCR2 that is recognized byboth 7G6 and 4E3 binds to C3d and less efficiently to C3b. Theseresults clarify the ligand specificities of MCR1 and MCR2.     

Zinc Ions Inhibit Factor I-Mediated Release of CR1-Bound Immune Complexes and Degradation of Cell-Bound Complement Factors C3b and C4b

ZnCl2 exerted a dose-dependent inhibition of citrate-phosphate-dextrose (CPD) plasma-induced release of 125I-labelled BSA-anti-BSA immune complexes (IC) bound to complement receptor type 1 (CR1, CD35) in human whole blood. Maximal inhibition was observed at 10 mM of ZnCl2. Furthermore, the release of IC bound to erythrocyte (E)-CR1 by purified factor I, factor I-deficient serum plus purified factor I, or normal human serum was reduced by approximately 90%, 64%, and 52%, respectively, in the presence of 10 mM ZnCl2. The effect of ZnCl2 on factor I-mediated degradation of cell-bound C3b/C4b was also investigated employing CPD blood or E from a factor I-deficient donor. These cells expressed covalently bound C3b and C4b as demonstrated by a simple agglutination technique. Upon incubation of CPD whole blood with purified factor I, or of E with purified factor I or normal CPD plasma, the C-fragments were cleaved and the cells were no longer agglutinated by antibodies to C3c and C4c. The presence of ZnCl2 prevented this factor I-mediated degradation of C3b and C4b, as evidenced by the unaffected agglutination of the cells by the antibodies. We conclude that ZnCl2 inhibited factor I activity since: (1) release of complement-preopsonized IC from E-CR1 by purified factor I was markedly inhibited (90%) in the presence of ZnCl2, (2) preincubation of the cells with ZnCl2 caused only a moderate inhibition (32-38%) of the IC release, and (3) degradation by purified factor I of covalently cell-bound C3b and C4b was abrogated in the presence of 10 mM ZnCl2.     

Defective complement receptors (CR1 and CR3) on erythrocytes and leukocytes of factor I (C3b-inactivator) deficient patients.

In view of a possible modulation of the C3b receptor (CR1) by its ligand, we studied a situation in vivo in which C3b is constantly present in the serum, i.e. the genetic factor I-deficiency. C3b and iC3b receptors (CR1, CR3) on peripheral blood cells, were analysed in three I-deficient (I-def.) patients, from two unrelated families. CR1 and CR3 were quantified by means of monoclonal antibodies, and functionally tested (phagocytosis of sensitized sheep erythrocytes (EIgG) or rabbit erythrocytes (Er), coated with C3b, and chemiluminescence (CL) induced by serum-opsonized zymosan). Erythrocyte CR1 levels were significantly lower in I-def. patients than in normal individuals. Monocytes and polymorphonuclear neutrophils (PMN) prepared at 4 degrees C, to prevent increase of CR1 expression in vitro, expressed low CR1 numbers. Monocytes prepared at room temperature showed a defective CR1-dependent phagocytosis and an impaired CL response, although their CR1 levels were found normal in these conditions. This discrepancy was also observed on phorbol myristate acetate (PMA)-activated cells. These CR1 abnormalities are likely to result from repeated interactions of CR1 with C3b molecules, which circulated in the serum of I-def. patients and were deposited onto their red cells. Although iC3b, the CR3 ligand, is not produced in I-deficient sera, monocyte CR3-dependent function (phagocytosis of unopsonized Er) was also found to be defective in two out of the three patients.     

Immune complexes bind preferentially to specific subpopulations of human erythrocytes

Primate erythrocytes have complement receptors (CR1) that, both in vivo and in vitro, bind immune complexes (IC) opsonized with C3b. The present study was undertaken to determine whether the ability of human erythrocytes to bind IC is a characteristic shared by all erythrocytes. Binding of IC to erythrocytes probably involves the interaction of several C3b molecules with several CR1 clustered in small areas of the erythrocyte surface. To identify IC binding CR1 clusters, we first assessed the binding to erythrocytes of fluorescein-labeled polystyrene beads coated with monoclonal anti-CR1 antibodies (anti-CR1-beads) and second, performed IC. The binding of these ligands to erythrocytes was evaluated by immunofluorescence microscopy and flow cytometry. We found that only a fraction of erythrocytes from normal individuals bound anti-CR1-beads specifically and the percentage of erythrocytes able to bind beads increased with increasing numbers of CR1 per erythrocyte. However, the number of anti-CR1-beads bound per erythrocyte varied among cells from the same individual. We demonstrated further that the erythrocyte binding sites for anti-CR1-beads are also binding sites for opsonized IC. This was shown by demonstrating that anti-CR1-beads inhibited the binding of opsonized IC to erythrocytes and opsonized IC inhibited the binding of anti-CR1-beads to erythrocytes. Incubation of erythrocytes with opsonized IC, followed by FITC-labeled secondary antibodies, confirmed that indeed only a fraction of erythrocytes is capable of binding opsonized IC and that the binding sites for IC occupy small regions on the erythrocyte membrane. By contrast, we demonstrated that greater than 90% of erythrocytes express CR1. In conclusion, only some erythrocytes have the capacity to bind IC. Differences in the ability of erythrocytes to bind IC are probably related to differences in the clustering of CR1 in the erythrocyte membrane. Anti-CR1-beads identify erythrocyte binding sites for IC. These beads should prove useful to assess the changes that occur in the erythrocyte CR1 after exposure to IC in vivo.     

Immune complexes and erythrocyte CR1 (complement receptor type 1): effect of CR1 numbers on binding and release reactions.

We performed experiments to investigate whether immune complexes opsonized with C3b and iC3b transferred from CR1 on one erythrocyte to CR1 on others, and studied the effect of variation in erythrocyte CR1 number on the transfer reaction. We used populations of cells of different blood groups to study this phenomenon which were separated by differential agglutination with monoclonal anti-group antibodies. The rate of transfer of immune complexes between erythrocytes was related to CR1 concentration of both donor and recipient cells; fastest transfer occurred from donor cells of low CR1 numbers to recipient cells of high CR1. These results were not explained by a difference in the binding constant of immune complexes to erythrocytes bearing different numbers of CR1. In the absence of factor I, complexes partitioned between erythrocytes according to their relative concentrations of CR1 with no release of complexes into solution. In serum, the proportion of complexes bound to donor and recipient erythrocytes was similarly related to their respective CR1 numbers with progressive release of complexes into solution. Erythrocyte CR1 may act as a dynamic buffering system which prevents immune complexes that have bound complement from fixing to vascular endothelium.     

Phagocytosis by receptors for C3b (CR1), iC3b (CR3), and IgG (Fc) on human peritoneal macrophages

Human peritoneal macrophages (HPM) obtained via laparoscopy were examined for the presence and functional capacity of complement and Fc receptors. Between 5 and 20 ml of peritoneal fluid containing 1-2 X 10(6) macrophages/ml was available for each study. Macrophages made up 80-95% of the cells in the fluid. Fc and C3 receptors on HPM were characterized by rosette formation with, and phagocytosis of, IgG- and C3-coated sheep erythrocytes (E). ElgG were bound by 82% and ingested by 63% of HPM, with 4-15 E ingested/HPM. The HPM formed rosettes with EC3b (56%) and EC3bi (71%) but not EC3d,g or EC3d. Antibodies to complement receptors type 1 (CR1) and type 3 (CR3) inhibited rosette formation with EC3b and EC3bi, respectively, indicating that HPM possessed separate and distinct receptors for the C3b and iC3b ligands. In 60% of the samples studied, HPM demonstrated the ability to ingest both EC3b and EC3bi, as well as ElgG. Because of the heterogeneous nature of the cells obtained in peritoneal fluid, due to their progressive change from monocytelike cells into mature macrophages, HPM were separated by 1 g velocity sedimentation into fractions of increasing maturity. They were then examined for phagocytosis via Fc and complement receptors. Fc receptor mediated phagocytosis occurred throughout the monocyte-to-macrophage maturation sequence, while the ability of HPM to ingest via CR1 and CR3 was maturation dependent, with ingestion via CR3 occurring before CR1, in a manner analogous to in vitro differentiation of monocyte-derived macrophages.     

An interaction between CD16 and CR3 enhances iC3b binding to CR3 but is lost during differentiation of monocytes into dendritic cells

The receptor for the iC3b fragment of complement, CR3, is involved in monocytes/macrophages and neutrophils phagocytosis. CR3 is known to interact with the low affinity receptor for Ig (CD16) and previous studies have suggested that this cooperation modulates CR3 functions. Herein we have studied the effect of CD16 on the ability of human monocytes CR3 to bind to iC3b. We show that iC3b binding to CR3 is inhibited by several reagents that are known to dissociate the CD16/CR3 complex. In addition, treatment of monocytes with soluble CD16 inhibited iC3b binding to CR3. Together, these data indicate that iC3b binding to monocyte CR3 is up-regulated by an interaction between membrane CD16 and CR3. The implication of CD16 in CR3 binding to iC3b was also analyzed after monocyte differentiation into dendritic cells (DC). Differentiation of monocytes into DC abrogates the cooperation between CD16 and CR3, due to a loss of CD16/CR3 interaction. In accordance, this phenomenon is associated with a lack of iC3b binding to DC. As a consequence, deposition of iC3b on apoptotic cells does not modify their phagocytosis by DC. In conclusion, we demonstrate a cooperation between CD16 and CR3 that favors iC3b binding to CR3 but is lost on DC.     

A CR1 polymorphism associated with constitutive erythrocyte CR1 levels affects binding to C4b but not C3b

The erythrocyte type one complement receptor (E-CR1) mediates erythrocyte binding of complement-opsonized immune complexes (IC), and helps protect against random deposition of circulating IC. Two linked CR1 polymorphisms occur in binding domains, at I643T and Q981H. In Caucasians, the variant alleles (643T, 981H) are associated with low constitutive E-CR1 expression levels. This study was conducted to determine if these polymorphisms affect ligand binding, and if so, represent risk factors for the autoimmune IC disease, systemic lupus erythematosus (SLE). In an ELISA comparing relative ligand binding differences, E-CR1 from individuals homozygous for the variant residues (643TT/981HH) exhibited greater binding to C4b, but not C3b, than homozygous wild-type E-CR1. Analysis of single-binding domain CR1 constructs demonstrated that the 981H residue imparted this enhanced C4b binding. No differences were observed in the 981H allele frequency between Caucasian controls (0.170, n = 100) and SLE patients (0.130, n = 150, P = 0.133), or between African American controls (0.169, n = 71) and SLE patients (0.157, n = 67). In a subset of individuals assessed for CR1 size, excluding from this analysis those expressing at least one B allele revealed a trend for over-representation of the 981H allele in Caucasian controls (0.231 frequency, n = 26) versus SLE patients (0.139, n = 83, P = 0.089), but again no difference between African American controls (0.188, n = 24) and SLE patients (0.191, n = 34). These data suggest that the 981H residue compensates for low constitutive expression of E-CR1 in Caucasians by enhancing C4b binding. This may contribute protection against SLE.     

Evidence for the Role of CR1 (CD35), in addition to CR2 (CD21), in Facilitating Infection of Human T Cells with Opsonized HIV

Complement activation by HIV results in the binding of C3 fragments to the gp160 complex and enhanced infection of C3 receptor-bearing target cells. We have studied complement-mediated enhancement of infection of the human CD4-positive T-cell line HPB-ALL which expresses the CR1 (CD35) and CR2 (CD21) receptors for C3. CR1 and CR2 are present on 15% and 40% of normal peripheral blood CD4-positive T lymphocytes respectively. Opsonization of the virus with complement resulted in a 3- to 10-fold enhancement of infection of HPB-ALL cells, as assessed by measuring the release of p24 antigen in culture supernatants throughout the culture period. Blockade of CR2 with cross-linked anti-CR2 monoclonal antibodies decreased infection to the level observed with unopsonized virus. Blocking CR1 reduced complement-mediated infection by 50–80%. Experiments using serum deficient in complement factor I demonstrated that CR1 mediates the interaction between opsonized virus and T cells in addition to its ability to serve as a cofactor for the cleavage of C3b into smaller fragments that interact with CR2. A requirement for CD4 in complement-mediated enhancement of infection was observed with HIV-1 Bru but not with HIV-1 RF. Thus, CR1 and CR2 contribute in an independent and complementary fashion to penetration of opsonized virus into complement receptor-expressing T cells. Involvement of CD4 in infection with opsonized virus depends on the viral strain.